Methods for generating composite images including filtering and embroidery price calculation

ABSTRACT

Methods for generating composite images are disclosed. A first image is selected via a Web interface presented on a browser and a second image is selected via a Web interface presented on the browser. The selection of the first image and the second image is communicated to a server via a network. A composite image is automatically generated, which includes filtering to simulate an appearance of the second image as applied to the first image according to a manufacturing process associated with a filter selection. If applicable, an embroidery price of the composite image is automatically calculated, the embroidery price comprising an estimated price for the application of a design represented by the second image to a product represented by the first image. The composite image, along with the calculated embroidery price (if applicable), is communicated from the server to the browser via the network.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of and claims the benefit of U.S.patent application Ser. No. 09/758,648 filed on Jan. 10, 2001 entitled“METHODS AND APPARATUSES FOR GENERATING COMPOSITE IMAGES;” which claimsthe benefit of U.S. Provisional Patent Application No. 60/176,956 filedon Jan. 18, 2000.

FIELD OF THE INVENTION

The present invention relates to the field of computer-generated images.Particularly, the present invention relates to the generation ofcomposite images at a server utilizing image selections communicated viaa Web browser over a network, such as the Internet.

BACKGROUND OF THE INVENTION

The sale of promotional products, also called advertising specialties,has traditionally been practiced as a broker-customer relationship wherea commissioned broker presents, in-person, various product lines anddecoration choices to a customer. For example, a customer may call abroker in regard to promoting their company at a client appreciationgolf tournament. The broker presents the customer with various products,i.e., hats, shirts, mugs, etc., that can be decorated using selecteddecorative technologies, i.e., embroidery, silk-screening, etc. Forexample, the customer may select a green polo shirt with the intentionthat it be decorated with company logo, graphic, name or other text orsymbol be in black embroidery above the shirt pocket. The broker thenfacilitates the coordination among the customer, product vendor, anddecorators to supply the requested customized product by the timerequired by the customer.

Due to the large number of product manufacturers and decorators, thebroker usually carries a selected product line from variousmanufacturers and utilizes a selected group of decorators to apply thenecessary decoration to the product. The customer, therefore, ispresented a limited group of products and options for decorating theproduct. Moreover, when choosing the product, the customer generally islooking at catalog images or samples that are blank—that is, undecoratedor decorated with the design of another company. In these cases, thecustomer is left to imagine the appearance of the decorated productuntil after placing an order. Thus, typically, the customer usually doesnot see the final product until it arrives. Furthermore, until theproduct arrives, the customer must depend upon the broker to ensure theorder is delivered on time and appears as was anticipated.

Thus, it would be desirable for a client to be able to select a productand a decoration at their convenience over a network, for example, theInternet, and to view the appearance of the final product.

SUMMARY OF THE INVENTION

The present invention discloses methods for generating composite imagesvia a network. In one embodiment, a first image is selected via a Webinterface presented on a browser. A second image is selected via a Webinterface presented on the browser. The selection of the first image andthe second image is communicated to a server via the network. Acomposite image of the first image and second image is automaticallygenerated at the server. The composite image is communicated from theserver to the browser via the network, wherein selection of a filter viaa Web interface presented on the browser is used in generating filteringinformation. The filtering information is communicated to the server viathe network. A composite image is automatically generated at the serveraccording to the filtering information to simulate an appearance of thesecond image as applied to the first image according to a manufacturingprocess associated with the filter. If the selection includesembroidery, an embroidery price is automatically calculated, theembroidery price comprising an estimate for the application of a designrepresented by the second image to a product represented by the firstimage. The server communicates the composite image, along with thecalculated embroidery price (if embroidery price is applicable), to thebrowser via the network.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example and notlimitation in the figures of the accompanying drawings, in which likereferences indicate similar elements and in which:

FIG. 1 is a diagram of a system architecture according to one embodimentof the present invention;

FIG. 2 is a flow diagram illustrating a product image processingaccording to one embodiment of the present invention;

FIGS. 3A and 3B are a flow diagram illustrating server side processesand client side processes utilized in generating a composite imageaccording to one embodiment of the present invention;

FIG. 4 is a Web interface presented on a browser that presents productdetails according to one embodiment of the present invention;

FIG. 5 is illustrating a product image file structure according to oneembodiment of the present invention;

FIG. 6 is a Web interface presented on the browser that enablesselection of a decorative image according to one embodiment of thepresent invention;

FIG. 7 is a flow diagram illustrating a process of uploading thedecorative image to a server according to one embodiment of the presentinvention;

FIG. 8 is a Web interface presented on the browser that presents adefault composite image according to one embodiment of the presentinvention;

FIG. 9 is a Web interface presented on the browser that presents acomposite image generated according to a warp ratio according to oneembodiment of the present invention;

FIG. 10 is a Web interface presented on the browser that enablespositioning of the logo image relative to a product image according toone embodiment of the present invention;

FIG. 11 is a flow diagram illustrating a process of relative positioningof the logo image;

FIG. 12 is a Web interface presented on the browser that presents aquote according to one embodiment of the present invention;

FIG. 13 is an example of a traditional client-server system upon whichone embodiment of the present invention may be implemented.

DETAILED DESCRIPTION

Although the present invention is described below by way of variousembodiments that include specific structures and methods, embodimentsthat include alternative structures and methods may be employed withoutdeparting from the principles of the invention described herein.

In general, embodiments described below feature a network-basedapplication that prompts a user for a product image selection and adecorative image selection and displays a product image (e.g., aphotograph) with the decorative image (e.g., a logo graphic or textgraphic) placed on it. A preferred embodiment of the present inventionfeatures a network-based application for composite image generation. Forthe purposes of the present specification, the term “product image”shall be taken to include any image type and may depict any type, shapeor construction of product. The term “decorative image” shall also betaken to include any image type, and may depict, for example, any logo,text, pattern, ornamentation, name, symbol, emblem or the like that maybe applied to a product.

In one embodiment, the present invention is implemented as acomputer-based service that may be accessed through the Internet, forexample, using a Web browser. The service provides an interface thatallows a user to select a product and select and/or create decorativeimage information and view the composite image before ordering thepromotional product.

Internet-Related Technology

As indicated above, one embodiment of the present invention provides anInternet-based implementation. Accordingly, some introduction toInternet-related technology is helpful in understanding the presentinvention. The Internet is a vast and expanding network of computers andother devices linked together by various telecommunications media,enabling the various components to exchange and share data. Sites(so-called Web sites), accessible through Internet, provide informationabout numerous corporations and products, as well as education,research, entertainment and services.

A resource that is attached to the Internet is often referred to as a“host.” Examples of such resources include conventional computer systemsthat are made up of one or more processors, associated memory and otherstorage devices and peripherals, such as modems, networks interfaces andthe like that allow for connection to the Internet or other networks. Inmost cases, the hosting resource may be embodied as hardware and/orsoftware components of a server or other computer system that includesan interface module, which allows for some dialog with users and thatmay process information through the submission of Web forms completed bythe user. Generally, such a server will be accessed through theInternet's graphical user interface, the World Wide Web, (e.g., via Webbrowsers) in the conventional fashion.

In order to facilitate communications between hosts, each host has anumerical Internet Protocol (IP) address. The IP address of ahypothetical host computer might be 112.222.64.27. Each host also has aunique “fully qualified domain name.” In the case of the hypotheticalhost 112.222.64.27, the “fully qualified domain name” might be“computer.domain.com”, the three elements of which are the hostname(“computer”), a domain name (“domain”) and a top-level domain (“com”). Agiven host looks up the IP address of other hosts on the Internetthrough a system known as domain name service.

As previously indicated, in order to access the Internet most users relyon computer programs known as “Web browsers.” Commercially available Webbrowsers include such well-known programs as Netscape's Navigator™ andCommunicator™ and Microsoft's Internet Explorer™. If an Internet userdesires to establish a connection with a Web page hosted atcomputer.domain.com, the Internet user might enter into a Web browserprogram the uniform resource locator (URL) “http://www.domain.com”. Thefirst element of the URL is a transfer protocol, most commonly “http”standing for hypertext transfer protocol, but others include “mailto”for electronic mail, “ftp” for file transfer protocol, and “nntp” fornetwork news transfer protocol. The remaining elements of this URL arean alias for the fully qualified domain name of the host.

Once a URL is entered into the browser, the corresponding IP address islooked up in a process facilitated by a certain computer, called thetop-level server. The top-level server matches the domain name to an IPaddress of a domain name server capable of directing the inquiry to thecomputer hosting the Web page. Thus, the domain name server ultimatelymatches an alphanumeric name such as www.domain.com with its numeric IPaddress 112.222.64.27.

When a host receives an inquiry from the Internet, it returns the datain the file pointed to by the request to the computer making theinquiry. Such data may make up a Web page, which may include a textualmessage, sound, picture, or a combination of such elements. A user canmove between Web pages through the use of hyperlinks, which are linksfrom one site on the Internet to another.

An integral component of the present invention is a computer server.Servers are computer programs that provide some service to otherprograms, called clients. A client 1305 and server 1310 of FIG. 13communicate by means of message passing often over a network 1300, anduse some protocol, a set of formal rules describing how to transmitdata, to encode the client's requests and/or responses and the server'sresponses and/or requests. The server may run continually waiting forclient's requests and/or responses to arrive or it may be invoked bysome higher-level continually running server that controls a number ofspecific servers. Client-server communication is analogous to a customer(client) sending an order (request) on an order form to a supplier(server) dispatching the goods and an invoice (response). The order formand invoice are part of the protocol used to communicate in this case.

Another component of the present invention is an alpha channel. An alphachannel is a portion of each pixel's data that is reserved fortransparency information. Pixel is the smallest addressable unit on adisplay screen. Typically, the alpha channel is defined on a per objectbasis; different parts of the object have different levels oftransparency depending on how much background needs to show through. Inshort, the alpha channel is a mask that specifies how the pixel's colorsshould be merged with another pixel when the two are overlaid, one ontop of the other.

Architecture

With these concepts in mind, an embodiment of a system architecture ofthe present invention can be explored. A composite image generationservice may be accessed through client machines 100 that run browserapplications 105 to provide graphical interfaces for a user toeffectively use the composite image generation service. The clientmachines 100 communicate with a server machine 120 via a network 110,e.g. Internet. The server machine 120 includes such components of thepresent invention as a web server 130, application sever 140 anddatabase server 150. It will be appreciated that these servers may runon other machines that are accessible by the server machine 120. In anembodiment of the present invention, databases for storing customerinformation, product image information, decorative image information,etc. are also stored at the server machine 120. However, it will beappreciated that databases may be stored at other machines and databasedata may be uploaded to the server machine 120 when necessary.

The application server 140 contains visualization server 150 thatincludes compositing engine 160, product image conversion engine 170 andartwork creation engine 180. Compositing engine 160 generates acomposite image based on a first image and a second image selected by auser. A first image is, for example, uploaded by a manufacturer of aproduct depicted in the first image and processed by the product imageconversion engine 170 for storage in a photo archive database 240.

Of course, the first image may be obtained from the any number ofsources. For example, an operator of a Web site that is it supported bythe server machine 120 may employ an internal photographic (or art)department that is responsible for generating images of products thatare supplied, together with pertinent product information, to the Website operator by manufacturers of such products. These internallygenerated photographs may be stored in a photograph archive database260.

The second image is modified by the artwork creation engine 180according to the user's operations in the Web browser. These imageconversion processes are described in detail below. The database server190 that communicates to the application server 140 contains databases191 used for the composite image generation. As stated above thedatabases may be stored at another machine and accessed by the databaseserver 190. Furthermore, the database server 190 may run at anothermachine and communicate with the application server 140 via the network110.

Methodology and User Interface

With these concepts in mind, an embodiment of the present invention canbe further explored. In order to produce a composite image, the firstand the second images, for example product image and logo imagerespectively, must be processed for use by the compositing engine 160 ofthe visualization server 150. While the below exemplary embodiment ofthe present invention is described as utilizing “logo images”, it willbe appreciated that the present invention is not limited to theutilization of such logo images, and may employ a decorative imagerepresenting any decoration (e.g., a graphic, logo or text) that may beapplied to product.

Before a product image and a logo image can be utilized by the compositeimage generator, in one embodiment, each is formatted as a raster file.It will be appreciated that the processing of the photo image need notoccur at the server and may take place at another location with theprocessed product images that may be, for example, uploaded to theserver via a network or generated by a Web site operator that operatesthe server machine 120.

In one embodiment of the present invention, a product image file issubmitted by a manufacturer. For example, the product manufacturersubmits a high-resolution product photo file, such as a file of 1.3mega-pixel resolution.

In another embodiment of the present invention the manufacturer maysubmit a physical product sample at 210 of FIG. 2 with the productinformation, including size, imprint area, etc., that is stored inproduct receiving database by the compositing engine 160. Upongeneration of photography instructions at 220, the digital photograph ofthe product is taken at 230 by, for example, a Web site operator thatoperates the server machine 120. The digital photograph is then uploadedto photo archive database 260. The coded photo with imprint areainstructions in the header of a product image file is stored in productdatabase 270.

In one embodiment, the product image processing may be done utilizing acommercially available software package, such as Adobe Photoshop™(available from Adobe Systems of San Jose, Calif.) on Windows™ operatingsystem (available from Microsoft Corporation of Redmond, Wash.). Analpha channel is defined using the selection tools in Photoshop™, and,at the same time, the diameter of the product is set and the warp ratiois automatically calculated based on the diameter of the product. Theproduct photo export plug-in generates the product image file andproduct thumbnail file and saves it in the product image database, orsaves it for uploading to the product image database by the productimage conversion engine 170. In one embodiment, the product imagedatabase may be part of a product database where the product images areassociated with a product; however, in other embodiments it may be aseparate product image database associated with a product database. Inan embodiment where the product images are processed at another system,the processed files are uploaded to the product image database. Theproduct image file may be a .png file containing a high-resolutionproduct image. It will be appreciated that product image files inaddition to or other than the above image files may also be generated bythe product photo export plug-in.

The next embodiment of the present invention is described with referenceto the simplified flow diagram of FIGS. 3A and 3B. At operation 301, acustomer on a client system 100 accesses the visualization server 150via a network 110 (e.g., Internet), utilizing a network browser. Thecustomer is presented on the browser with a Web interface (e.g., HTMLdocument) communicated from the visualization server 150, and promptingthe customer to enter a user identification (userid) and password inorder to use the composite image generation service. First time usersare prompted to enter customer information, e.g. name, address, phonenumber, billing address, payment information and are assigned a useridand password that are user-modifiable. Upon entering a userid and apassword, the information is sent to the visualization server 150, wherevalidation of the entered information is done against a customerdatabase containing all the relevant customer information. Uponsuccessful validation access to the composite image generation serviceis provided to the user at operation 302.

At operation 303 the user may browse a virtual product catalog or searchfor a specific product. If the user selects a search option then thevisualization server 150, upon getting a search request, conducts asearch for a product against a product database that may be stored onthe server machine 120 or on another machine that is accessible by thevisualization server 150. The user is presented with a list of all theproducts stored in the database or the list of products identified bythe visualization server 150 as the result of a specific product search,along with thumbnail image of each product next to its name. Uponclicking on a thumbnail image the user may be presented with theenlarged photograph 402 of a product with the detailed description. Anexemplary user interface 400 to present the enlarged photograph 402 isshown in FIG. 4. At this point 305 the user may select a product fordesign. A unique product identification number gets sent to thevisualization server 150, which allows the server to select the correctproduct photo with the specialized imprint instructions from the productdatabase. In one embodiment of the invention each product image may bestored in a file 510 with the header 520 containing information aboutthe image, such as size, imprint area, warp ratio, etc., as illustratedin FIG. 5. It will be appreciated that the selected product image ismaintained as an image file accessible at the server machine 120 and mayreside as an image file in a separate product image database or mayreside as an image file in part of a larger database, such as theproduct database.

After selecting a product for design, the user may select the secondimage, at operation 307, which may be artwork, such as a logo. It iscustomary for businesses to have several versions of a company's logo,these versions can be stored in the customer database, and upon customerlogin may be transferred to a Web browser for display. An exemplary userinterface 600 to present user's logos 610 is shown in FIG. 6. In analternative, the user may upload a logo from the client to thevisualization server 150 through operations illustrated in FIG. 7. At701 upon user's selection of upload option the user is presented with aform for browsing files stored at the local computer. At operation 702the user selects a file that may be a .jpg, .bmp, .eps, or .tif anduploads it to the visualization server 150 where the number of colorsand transparent area are detected by the artwork creation engine 180.The visualization server 150 displays the analyzed logo on the Webbrowser on a specialized background, at operation 703. At this point704, the user may edit artwork transparency areas and submit changes tothe visualization server 150. The server then, at 705, re-displays thelogo with the changes on the Web browser. Upon satisfaction with thelogo the user may save the logo and associated data in an artworklibrary database at the visualization server 150.

Returning to FIGS. 3A and 3B, when the user finalizes the product choiceand logo selection the server communicates the composite image to thebrowser via the network, illustrated as operation 309 of FIG. 3A, andthe composite image of the product and the logo is displayed at the Webbrowser, where the logo is placed in a default position on the product,e.g. the logo will be placed in the center of a baseball cap as adefault. An exemplary user interface 800 to present a default compositeimage 810 is shown in FIG. 8. Necessary warping is applied by thecomposite engine 160 when generating default composite image. Theproduct image file selected by the user contains warping information,e.g. warp ratio, in the header of the file. The composite engine 160places the logo image on the product image according to the warp ratio.An exemplary user interface 900 to present a composite image 910containing warping is shown in FIG. 9. The warping may be cylindrical orspherical, however, it will be appreciated that the warping ratio may befurther defined to address other types of product image topography, e.g.undulating, cubist, etc.

However, the user is not limited by the default composite image. In oneembodiment, the user can selectively position a logo image relative tothe product image by selecting a position on a positioning grid 1006presented, at 1110 of FIG. 11, via a Web interface on the browser, asillustrated in exemplary user interface of FIG. 10. For example, theuser may select block 1008 in positioning grid 1006 by navigating acursor over block 1008 and clicking on it. The selecting of block 1008generates positioning information that is communicated to thevisualization server. Upon the user changing relative position ofartwork and text, new placement coordinates are calculated by thevisualization server 150 based on the grid selection, size of theartwork and text and imprint area at 1120 of FIG. 11. This method wouldbe best described by the following example. Let the grid be 5 blocks by5 blocks, as illustrated in FIG. 10. The imprint algorithm 165 of FIG. 1divides the imprint area by 5 and performs relative positioning upon theuser selecting grid blocks. For example, if an imprint area is a 1-inchrectangle then a change by one block is 2/10 of an inch move. Thechanges are being sent to the visualization server 150, where the image1004 is being re-composited and re-displayed on the screen at 1130 ofFIG. 11.

In addition, the visualization server 150 makes some assumptions aboutthe size of the logo when generating the default composite image, andthe user is given an option to modify it. The user may be presented witha drop down menu 1010, where the user may select the desired size byselecting and clicking on a small, medium or large option. Uponreceiving the request the visualization server 150 re-sizes the image,re-composites the image and re-displays it on the Web browser. Forexample, if the user wants the logo to be of a small size, thevisualization server 150 may re-size the logo to a 33% of an originallogo image.

FIG. 10 illustrates an example of a Web interface presented on a browserthat allows the user at the client side to select a manufacturingprocess filter to use in generating a composite image. In oneembodiment, the user is presented a selection of filters via a Webinterface presented on the browser. For example, the user may bepresented a display of manufacturing techniques or processes in aselection box 1001. For example, the selection box may display a dropdown menu of options for selection by the user. The user may then selecta filter 1002, for example, by scrolling down the drop down box andclicking on a selected filter. The selection of the filter generatesfiltering information that is communicated to the visualization server150. This filtering information is used in generating the compositeimage so that the logo appears applied to the product image according tothe selected filter, i.e., embroidery, silk-screening, engraving, etc.This technique is accomplished by the usage of filters that are wellknown in the art.

Upon completion of operation 312 of FIG. 3A, the design is stored in aproject folder database at the visualization server 150 and finalartwork for production is generated and stored in an order database at313. The user is then presented with a quotation form, illustrated inFIG. 12, where such information as quantity, color, decoration process,special instructions from the customer, etc. needs to be filled out.Upon the user completing the form the visualization server 150calculates the price for the order at operation 315 of FIG. 3A. Anautomatic and accurate price calculation is one of the goals of thepresent invention. The price of the promotional product with theimprinted logo depends on the methods of manufacturing. For example, ifimprint is done by the method of embroidery then the number of stitchesdetermines the price of the order. When the final design is finalized bythe user and the visualization server 150 is ready to calculate thequote, the number of stitches is calculated. The number of stitches isdirectly proportional to the size of the logo and depends on the ratioof non-blank pixels to the imprint area. The visualization server 150measures the number of pixels occupied by the artwork and calculatesthis area in square inches, then multiplies the area by the averagenumber of stitches per square inch that is stored in the header of theproduct image file.(Logo area in square inches)×(Average number of stitches per squareinch)This calculation technique allows the user to rely on pricing beforeplacing the order, rather than waiting for the embroider to apply thedesign and then determine the number of stitches used in making thefinal design. For example, if an imprint area is 200 pixels and it is 5inches wide, and the logo is 100 pixels, then two and a half inches isgoing to be multiplied by the average number of stitches per squareinch. In another embodiment of the present invention, the average numberof stitches per square inch can be user-modified. The only change thatneeds to be made to the above calculation process is that instead ofretrieving the average number of stitches from the header of the productimage file, the value is sent to the visualization server 150 upon theuser entering it at the Web browser. Based on the calculated oruser-modified number of stitches per square inch and an embroidery priceprovided by various embroiders the fixed price quote may be calculated.

The user is then presented with the fixed price quote and a photo sampleaccording to the information stored in the databases (i.e. productdatabase, order database). The photo sample addresses the need for apre-production proof feature that is well known in the industry. Insteadof waiting for a manufacturer to complete a sample of a promotionalproduct, the user can view the final product on the Web browser in thecomfort of his/her own office.

In one embodiment of the present invention, the photo sample image maybe generated to include filtering so that the composite image simulatesthe appearance of the logo applied to the product according to aselected manufacturing process or technology. In another embodiment ofthe present invention, the user may zoom in and out of the photo sampleto view the image in greater detail. This feature is implemented usingthe techniques well known in the art.

In one embodiment of the present invention, the user may choose to senda finalized image for approval to a supervisor. Upon selection of thisoption, the visualization server 150 compiles an e-mail message andsends it to a specified e-mail address with an image of the finaldesign, or, in the alternative, with the URL of the Web site where thefinal design image may be viewed.

Upon accepting the fixed price quote, operation 316 of FIG. 3B, theorder details are written into the order database on the visualizationserver 150. The request for shipping and billing information is beingdisplayed on the Web browser for the user to fill out. In thealternative, the customer shipping and billing information stored in thecustomer database may be displayed on the Web browser for validation.When shipping and billing information is validated or entered into theorder database, the payment method is requested. Upon entering of thepayment method at 320 and validation of it at 321, the transaction withthe user is complete. At this point the order, shipping and billinginformation is formatted and sent to the supplier. In one embodiment ofthe present invention all the necessary information about the customerorder is formatted into an email message form and sent to a supplier.

In the foregoing specification the present invention has been describedwith reference to specific exemplary embodiments thereof. It will,however, be evident that various modifications and changes may be madeto the specific exemplary embodiments without departing from the broaderspirit and scope of the invention as set forth in the appended claims.Accordingly, the specification and drawings are to be regarded in anillustrative rather than a restrictive sense.

1. A method for generating a composite image including: presenting afirst image via a Web interface presented on a browser; presenting asecond image via a Web interface presented on the browser; communicatinga selection of the first image and the second image to a server via anetwork; automatically generating a composite image of the first imageand the second image at the server; and communicating the compositeimage from the server to the browser via the network; wherein thecomposite image further includes filtering to simulate an appearance ofthe second image as applied to the first image according to amanufacturing process associated with a filter selection.
 2. A methodfor generating a composite image including: presenting a first image viaa Web interface presented on a browser; presenting a second image via aWeb interface presented on the browser; communicating a selection of thefirst image and the second image to a server via a network;automatically generating a composite image of the first image and thesecond image at the server; communicating the composite image from theserver to the browser via the network; selecting a filter via a Webinterface presented on the browser, the selection of the filtergenerating a filtering information; communicating the filteringinformation to the server via the network; and automatically generatingthe composite image at the server according to the filtering informationto simulate an appearance of the second image as applied to the firstimage according to a manufacturing process associated with the filter.3. The method of claim 2 wherein the filter selection is embroidery. 4.The method of claim 3 further including automatically calculating anumber of stitches.
 5. The method of claim 2 wherein the filterselection is silk-screening.
 6. A network-based method for generating acomposite image, the method including: receiving a first image and asecond image at a server from a browser responsive to a user-selectionof the first image and the second image; automatically generating acomposite image of the first image and the second image at the server;and communicating the composite image from the server to the browser viaa network; wherein the composite image includes filtering to simulate anappearance of the second image as applied to the first image accordingto a manufacturing process associated with a filter selection.
 7. Anetwork-based method for generating a composite image, the methodincluding: receiving a first image and a second image at a server from abrowser responsive to a user-selection of the first image and the secondimage; automatically generating a composite image of the first image andthe second image at the server; communicating the composite image fromthe server to the browser via a network; and receiving a filteringinformation from a client via the network and automatically generatingthe composite image at the server according to the filtering informationto simulate an appearance of the second image as applied to the firstimage according to a manufacturing process associated with a filterselection.
 8. A network-based method for generating a composite image,the method including: presenting a first image for user selection via afirst Web interface presented on a browser; uploading a second image;communicating a selection of the first image and the second image to aserver via a network; receiving a composite image of the first image andthe second image from the server at the browser via the network; anddisplaying the composite image via a second Web interface presented onthe browser; wherein the composite image further includes filtering tosimulate an appearance of the second image as applied to the first imageaccording to a manufacturing process associated with a filter selection.9. A network-based method for generating a composite image, the methodincluding: presenting a first image for user selection via a first Webinterface presented on a browser; presenting a second image for userselection via a second Web interface presented on the browser;communicating a selection of the first image and the second image to aserver via a network; receiving a composite image of the first image andthe second image from the server at the browser via the network; anddisplaying the composite image via a third Web interface presented onthe browser; wherein the composite image further includes filtering tosimulate an appearance of the second image as applied to the first imageaccording to a manufacturing process associated with a filter selection.10. An apparatus for generating a composite image including: a firstimage database, the first image database to store at least one firstimage file; a second image database, said second image database to storeat least one second image file; and a server to receive a user selectionof the first image file and the second image file and to generate acomposite image of a first image and a second image wherein the secondimage is positioned relative to the first image; and wherein the serveris further configured to generate the composite image according to afiltering information to simulate an appearance of the second image asapplied to the first image according to a manufacturing processassociated with the filtering information.
 11. An apparatus forgenerating a composite image including: means for presenting a firstimage via a Web interface presented on a browser; means for presenting asecond image via a Web interface presented on the browser; means forcommunicating a selection of the first image and the second image to aserver via a network; means for automatically generating a compositeimage of the first image and the second image at the server; and meansfor communicating the composite image from the server to the browser viathe network; wherein the means for automatically generating a compositeimage are further configured to generate the composite image accordingto a filtering information to simulate an appearance of the second imageas applied to the first image according to a manufacturing processassociated with the filtering information.
 12. A method for generating acomposite image including: presenting a first image via a Web interfacepresented on a browser; presenting a second image via a Web interfacepresented on the browser; communicating a selection of the first imageand the second image to a server via a network; automatically generatinga composite image of the first image and the second image at the server;automatically calculating an embroidery price of the composite image,the embroidery price comprising an estimated price for the applicationof a design represented by the second image to a product represented bythe first image; and communicating the composite image along with thecalculated embroidery price from the server to the browser via thenetwork.
 13. The method of claim 12 wherein the automaticallycalculating the embroidery price includes calculating the second imagearea.
 14. The method of claim 13 wherein the automatically calculatingthe embroidery price of the composite image further includes multiplyingthe second image area by an average number of stitches in a predefinedarea.
 15. The method of claim 14 wherein the average number of stitchesin the predefined area is stored in a product image file.
 16. The methodof claim 14 wherein the average number of stitches in the predefinedarea is modifiable by a user.
 17. The method of claim 13 wherein theautomatically calculating of the embroidery price of the composite imagefurther includes utilizing an embroidery price of a number of stitchesin a predefined area.